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Abstract
Introducing pores is an effective approach for fabricating ultralow-εr ceramics; however, it is still unclear how the microstructures affect the microwave dielectric properties. In the present work, Al2O3-A and Al2O3-B porous ceramics were prepared by incomplete sintering at 1,000-1,650 °C and sintering at 1,650 °C with a porogen, respectively, so that the effects of porosity and ceramic connectivity can be clarified. The introduction of pores led to a significant decrease in εr, Qf, and |τf|, and Al2O3-B ceramic exhibits a slightly higher εr, a larger |τf|, and a much higher Qf value compared to the Al2O3-A counterpart with a similar relative density. For Al2O3-A, increasing the sintering temperature and relative density notably enhanced ceramic connectivity, while Al2O3-B's ceramic connectivity remained relatively insensitive to density variations. The improved ceramic connectivity in Al2O3-B enhanced the contribution of the ceramic phase to εr and τf, while also increased the Qf value by reducing ceramic-pore interfaces. Notably, Al2O3-B, with a low relative density of 48.31%, demonstrated a good combination of microwave dielectric properties, with εr = 4.16, Qf = 38,400 GHz, and τf = -44.3 ppm/°C. These findings reveal the strong dependence of microwave dielectric properties on ceramic connectivity in porous ceramics, and also inspire the development of ultralow-εr materials by regulating both the porosity and ceramic connectivity.
Keywords
Porous ceramics
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Al2O3
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ceramic connectivity
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ultralow dielectric constant
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microwave
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Xiao Jian Yan, Meng Cao, Lei Li, Shu Ya Wu, Xiang Ming Chen.
Dependence of microwave dielectric properties on ceramic connectivity in ultralow-εr Al2O3 porous ceramics.
Microstructures, 2025, 5(3): 2025065 DOI:10.20517/microstructures.2024.202
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